Condition responsive device



March 9, 1954 J. A. SENN CONDITION RESPONSIVE DEVICE 3 Sheets-Sheet 1 Filed June 15 1951 1N5 LATIUN LN u TIUN INVENTOR. JURE A. SENN iii:

Eiklri Chi l ATTIIIRNEYS J. A. SENN CONDITION RESPONSIVE DEVICE March 9, 1954 3 Sheets-Sheet 2 Filed June 13, 1951 INVENTOR. .JLI'RE A. EENN ATTURNEYE March 9, 1954 J. A. SENN CONDITION RESPONSIVE DEVICE 5 Sheets-Sheet 5 Filed June 13 1951 I INSULATIUN R N 5 m N Y N E I E E5 N V. R WA w E T R. LT U A J M Patented Mar. 9, 1954 CONDITIONVRESPONSIVE DEVICE Jiirg;A. 'Snn, Milwaukee, Wis., assignor vto Perfex Corporation, Milwaukee, Wis.', a corporation of Wisconsin Apblicalt-ion 'llune 'lb, 1951, Serial No. 231,312

. 10 Claims; 11

This invention relates to a- -condition-. responsive-device and-more particularlyto that itypeof condition responsive device wherein a switch mechanism is utilized to controliapparatusflin response to variations---in-val=ue-ofra condition,

suchas temperature or pressure.

An object of this invention'is to provide a condition responsive-device capab1e of operating- -as a fan control and-with modifications, as alimit control for a heating system with a maximum number of inter-changeable parts: in-the two forms to facilitate manufacture and repair.

Another obj ect of the-invention is to :providea limit control utilizing zunique fail safe features to furnish complete-shutdown-of the heating system inthe event pt failure of thecondition responsive element Another-object er the invention islito provide means in the formof. pointers .-and=scales to permit resetting ofthe deviceion different itemperature operations and .for indicating-the temperature setting. thereof asdesiredv A still further object sofa the: invention ;is to provide a novel arrangement of levers and abutments to efi'ect the required switchingaaction under all conditions-bf ioperationcincludingr fails ure or rupture ofthe-conditiom-responsiverelement.

These and further.objectswilibecome apparent as thisdescription proceeds-and-willbe particularly pointed out intheappendedelaims;

Reference is-now-to be had :to the accompany ing drawings in which: 1

Figure l is afrontview, partially insection, of the fan switch portion of the device;

Figure 2 is a iront view; partially 'in section, of the limit switchportion -of -,the\;device;

Figure 3 is a schematic view=of the limit switch portion shown in the hotttrip positiom Figure 4 is a schematic view of the limit switch portion shown in the'"cold trip position;

Figure 5 isa schematic-view of -the-limit: switch portion shown in the fail isafe zpositi'on'; T

Figure 6 is a-schematic WiQW'sOf amcdifiedr-form of the limit switch showmin itheflfailisafe. i110:- sition;

Figure 7 is a .leftsidevievn'apartialiy in-rsection', of the limit switchmf Figured;

Figure Bdsaright sideview; partially-in: section, .of. the limitiswiteh of=Eigure- 2; and

Figure 9 is a-planview taken alongs the dines IX-IXof Figure 2- Referring now to Figures eldands 2, in which @is shown metal casing: ,I q nonsistingi ofiend plate 12, front -plate l-i tremoved; Figs. -1 and 2 butshown in Figs. 7 and.8), base plate.,l4,.=rear plate 15, and end plate I6.-. The base plate. M has .a .-protrudingboss l8 and an aperture. 20. The aperture enables a condition responsive element 22,. fastened to the base Hi, to perform afunction within the casing H] in responseto anrexternal condition. The condition responsive element 22 maybe any type of element thatresponds to temperature or pressure to perform linear motion, but the preferred typeisthe one shown. The typeof condition responsiveelement shown consists of a receptacle 24 secured towthe base|4 by means of welding or-screws, a pair of nested diaphragms 26 and28, and-a hollow tube 30 communicating with the area between the diaphragms 2t and 28. The tube 30 extends to a bulb (not shown) placed in proximity toza condition to be controlled in such a manner that the bulb and tubeare effected by changes in the condition, such .as temperature changes in the bonnet of a hot air furnace. The bulb isusually filled with a thermally-expansible fluid which expands. on temperature increases and contracts on temperature decreases. This fluid filled-systemis designated as the condition responsive element 22. The upper diaphragm 26, .whichis one of .the two movable portions of the condition responsive element 22, has'resting thereon, a head portion 32 ofa threaded bolt 34. The bolt 34 is screw threaded within .a gimbal base 36. The gimbal base 36 has two gimbal ears-38 and 39, fulcrumly attached to a channeled-lever (hereinafter called the main lever) bymeansof a struck-out portion and 45 (Figure 8) of lever 40. A-spring 44 is interposed between the gimbal base 36 and the base 46 of the main lever 40 to perform a dual-function, as follows; the spring 44 actsas a resilient retainer for the-gimba-l base 36-and the main lever 46 to allowarrelative pivotal movement between them under linear movement of the gimbal base it, and the spring 44 also acts as a strain relief spring under certain conditions when the main lever 48} ispivoted to its uppermost position and-continued-travel of the movable diaphragm 25 -neccessita tes continued travel of the gimbal base. This latter function-helps to prevent rupture of the con:- dition responsive elementunder excessively high temperature conditions of operation.

The main lever .40 has side channels 5831111159 bent at rightangles' to the base Axpinz52ris pivotally mounted on the'casing: andv extends through apertures. in the side.channelss itiand-sfit. This pivot ,pin :52- is the primary pivot of: the-deviceaa-nd the: only-fixed pivot extendingsthroug'h 3 the cover plates I3 and I5 of the casing I8 (Figure 8). A bent over end piece 54, an extension of base 46 of main lever 48, is threadably apertured to receive two retaining screws 55 and 58 (Figure 8), which hold a permanent magnet 58 against the end piece 54.

At the left end of main lever 48, a pivot pin 68 pivotally connects the main lever 48 with a second channel shaped lever 62 (hereinafter called the trip lever), which lies within the sides 48 and 58 of main lever 48. The trip lever 62 has an apertured base 64 through which extends the spring 44 and other parts to be later described. At the right end of trip lever 62 (Figs. '1 and 2), the base 64 has riveted thereto a U-shaped bracket 66 which acts as a dual armature for magnet 58. The lower armature leg 68 of bracket 66, as shown, is in magnetic attraction with the magnet 58. The upper armature leg I8, as shown,

is spaced away from the magnet 58.

At the left end of trip lever 62 (Figs. 1 and 2), the base 64 has riveted thereto an abutment finger 12 which co-acts with abutments to pivot the trip lever 82 about the pivot pin 68, in a manner to be further described. A compression type spring I4 is interposed between the cover I6 and a boss 18 on main lever 48 to bias the lever assembly (48-48-62) in a downward direction. The spring I4 acts in opposition to the expansible force of condition responsive element 22 as directed against the lever assembly.

The upper armature leg I8 of bracket 65 has riveted thereto a bracket 88 which supports an insulation trip bar 82. The bar 82, integral in movement with trip lever 62, engages a control instrumentality, herein shown as a switch mechanism.

The parts heretofore described are the parts common to both the fan control of Figure 1 and the limit control of Figures 2, 7, and 8, with a few minor exceptions.

Referring specifically to Figure 1, the fan control will now be described. In the operation and control of a hot air heating system, for example, the intermittent operation of a fan or blower to disseminate heated air within a room or other enclosure is a desirable function. The usual method is to provide thermostatic operation of the fan upon the attainment of a set temperature of say 120 F. with continued fan operation until the bonnet temperature drops to say 100 F., whereupon fan operation ceases. In the present invention provision is made for the on-operation of the-fan at any preferred setting and also for shut-off of the fan at a preferred lower setting.

In Figure l the higher setting (120 F.) for on-operation of the fan is obtained by manual rotation of a serrated disc 84 having a pointer 86, designating the degrees of temperature on a scale (not shown). The scale may be graduated in degrees from 75 F. to 155 F., impressed on the face of the cover member I6. The disc 84 is rigidly secured to a shaft 88 by means of a set screw '88 threaded in the disc 84. The shaft 88 is secured at its other end to a threaded plug 98. The plug 98 is received in a threaded collar 92 secured to the protruding boss I8 by brazing, soldering, or other suitable means. Thus, rotative movement of the disc 84 results in rotation and consequentially vertical movement of the plug 98 within the collar 92. The upper surface of plug 98 defines an abutment 94 which co-acts with the finger I2 of trip lever 62 upon movement of the lever assembly (48-68--62) in a downward direction. Dlflerent manual settings of the disc 84 4 vary the height of the abutment 94 to vary the distance through which the finger 12 must move for engagement with abutment 94.

A serrated, disc-shaped knob 96, concentric with disc 84 and shaft 88, is provided for adjustment of the lower temperature or the off-position of the fan. The knob 96 is integral with a threaded plug 98 adjustable within a threaded collar I88. The collar I88 has affixed thereto a flanged boss I82 formed in the cover member I6. A serrated disc I84 having a pointer I85 is fastened by screws or other suitable means to the knob 96. The pointer I85 utilizes the same scale as the pointer 86, in the same manner as the hands of a clock. Manual adjustment of the knob 96 varies the height of an abutment I88 on the plug 98. The abutment I86 co-acts with finger I2 of trip lever 82 in the upward direction of travel of the lever assembly (48-68-62).

An insulation cover member I88 supports the switch contact structure to be subsequently described. Terminal screws I89 and H8 furnish a means for external connection to the fan and electric power supply (not shown). U-shaped clamps III and H2 provide securing means for the screws I89 and H8 and the switch contact structure on the opposite side of the switch supporting member I88. The strip II4 extends in a generally U-shape, to a switch arm I28. The switch arm I28 supports a contact I22. The arm I28 is spaced from the switch supporting member I88 by the branch H 8 of a rigid strip II6. A U-shaped strip I24of spring-like conductive material is secured by the inturned ends of clamp I I2 against the switch supporting member I88. A switch arm I26 of strip I24 overlies the arm I28 (Figure 1) and supports a contact I28. An extension I38 of arm I26 is spring biased downwardly against the insulation trip bar 82. A hole I32 in strip II4 provides a means for resetting the switch contacts to closed position. A reset button I34, loosely journaled in the cover 16, has a rod portion I36, larger in diameter than the hole I32 and a smaller extension I38 protruding through the hole I32. A spring I48 interposed between the button I34 and the cover 16 biases the reset to its uppermost position. A latch pin I42 perpendicularly secured to the rod I36 enables an operator to depress the button I34, turn the button I34 a half-turn and latch the pin I42 beneath the switch supporting member I88. This pivots the arm I28 of strip 4- counter-clockwise about the branch II8, moving contact I22 into engagement with contact I28. With the parts in the position shown in Figure l the contacts (I22- I28) would normally be open because the trip bar 82 is in its uppermost position, but as shown the reset button has pivoted the arm I 28 and contact I22 upwardly into engagement with contact I28.

Fan control-operation With the device in the position shown in Figure 1 and the reset button I34 turned to the unlatched position instead of the latched position as shown, the contacts (I22I28) are in the open position. The circuit to the fan motor and electric power supply will then be open.

Assuming an on-fan setting of 120 F. has been made with disc I84 and an off-fan setting of F. has been made with disc 84, the starting of a heating cycle- 'will initiate operation of the device. The remote bulb (not shown) is usually placed in the bonnet of I the furnace where it will respond to the temperature of the heatedair. After a period of heatlngfsuflicientto raise the temperature of the bonnet air to 120 F." the fluid in the thermo-responsive bulb will have "expanded proportionally. This expansion will be reflected through the tube 30 intothe'area between diaphragms 26 and 28', forcing the upper diaphragm 26 to flex upwardly. The expansion of the diaphragm 26 carries the head portion-32, the gimbal base 36 and gimbal ears 38, 39 upwardly, causing the lever'assembly (40-60- -62) to pivot clockwise about the pivot pin 52. This pivotal movement raises the opposite end of the lever (40'-60-62) upwardly against thebias of spring I4 until the abutment finger I2 engages the abutment I06 at which point the trip lever 62 breaks away frommain lever 40 to pivotclockwise about the pivot pin 60. The right end of trip lever 52, carrying'the armature bracket 86, pulls away from the main lever 40, pin 52' and magnet 58. A snap action results which pulls armature leg I into engagement with the magnet 58. This causes the insulation trip bar 82 to release the spring-biased extension I30 of arm I26 to close the contacts (i22l28). Closure of contacts (I22I28) completes the fan circuit to start the fan operation, circulating heated air through the duct system. The fan will operate continuously "until the bonnet temperature drops to 100 1 With a decrease in bonnet temperature, the

diaphragm 26 will collapse proportionally, carry- 0 ing the gimbal assembly (36, 38 and 33), and lever assembly (406062') downwardly under the bias of spring 14. This movement will pivot the lever assembly (4060-62) counter-clockwise about the pivot pin 52 until the abutment finger I2 engages the abutment 94, at which point the trip lever 62 will again break away from main lever 40 to pivot counter-clockwise about the pivot pin 60; The armature leg will pull away from the magnet 58 and the armature leg 68 will be attracted to the magnet 58 resulting in an upward snap action of the bracket 66. This will cause the trip bar 82 to engage the extension I; carrying the contact I28 upwardly, out of engagement with the contact I22. This opens the fan circuit untilthe bonnet temperature again rises to 120 F., atwhich setting,.the on-operation is repeated.

The re-set button I34 maybe manually operated at any time to either close the fan circuit, if open, or maintain the fan circuit in closed position, if closed. This function is desirable under many instances, for example during warm weather, when the heating system is inoperative, to circulate air to provide a cooling function. The re-set operation may also be required in the event of failure of the condition responsive device to close the contacts and excessive heating of the furnace would result in objectionable hazards. Manual operation of the fan switch enables the excess heat to be dissipated more rapidly to prevent over-heating oi the furnace.

The operation of the reset feature is 'as'follows: With the contacts (I22- -I28) in the open position, the switch arm I20 lies" parallelwith the switch supporting cover I08. on manual depression of the re-set button I34 against the bias of spring I40, the rod portion I36 engages the switch arm I20 at the hole I32. The smaller diameter extension I38 of rod I36 extends through the hole I32. The downward movement of rod 136 pivots the switch arm I20 counterclockwise about the branch II 8 to bring contact I 22 into engagement with. contact I28 The reset button 134 isa-latched im this new -posi tion by rotating the re-set button I 34' 'which' turns the rod I and latch pin I42 until the pin I42 isin the position shownat whichs'point the re-"setbut' ton I34 is released. The switch supporting member I08 holds thepin I42 and the re-setbutton in the position shown. Rotation of the 're-set button I34 will cause the pin I42 to slip off the switchisupp'orting member" I08 and the spring I will return the switch to open position.

Limit controldescription Referring to Figures 2, 7. 8, and 9, the linfiit control portion-of the invention willhow'be described' Note, that the switch elements of Figure 1 are in a reversed position. The lower contact arm I44 carries the extension I46 which corresponds to the extension I30 of Figure 1. The upper contact arm I48 overlies a depending branch I50 which corresponds to thebranch II8 of Figure l. The upper contact arm I48 sup ports a contact I52 in proximity to a contact I54 on arm I44. A hole I55 in the arm I48 permits a rod I56 to move freely therein. The head I58 of rod I56 is larger in diameter than the hole I55 to engage the arm I48 after a predetermined distance in a downward direction has been reached. The rod I56 is secured at its other end tothe channel base 46 of channelmain-lever 40. It may be either welded or adjustably retained at the channel base 46.

The threaded plug 98a" with its abutment I'06'ahas been raised by turning the disc I04 and pointer I55 counter-clockwise to a setting of 200 F., for example (a higher scale graduated from F. to 250 F. is used for the limit control). The limit control has the function of opening the entire heating control-circuit upon the attainment of a high temperature to prevent overheating of the furnace beyond a safe maximum temperature. For purposes of explanation a temperature setting of 200 F. has beenmade but obviously any preferredsetting may be used, depending upon the particular heating requirements, condition of furnace, etc. This-temperature (200 F.) represents the temperature threshold above which the heating system is unsafe. Shutdown may be maintained until the temperature drops to F., for example, before the device again energizes the heating system. This difference (180 F.-200 F.) is dependent upon the operating differential as determined bythe adjustable abutment I 06a in relationto an abut ment collar I60 and a spring I62. The abutment collar I66 is loosely, contained concentric with the shaft 88a, for'longitudinal movement therewith under the bias of spring I62. Note, that the shaft 380., though comparable with shaft 88 is not secured to the lower abutment as in Figure 1. It acts merely as a guide for the-abutmentassembly. Thus there is an adjustable fixed abutment I 03a for upward travel of lever assembly (40--60-62) and a non-adjustable resilient abutment I60 for downward travel of lever assembly (40-60-62). Note, that the increased distance for upward travel of lever assembly (40-60-32) in Figure 2 is commensurate with the increased temperature setting in Figure 2' (200 F.). I

For assembly purposes a latch-type retainer I64 serves to hold the spring I 62 and abutment collar I60 in place against the boss I8;

Limit controloperation I Referring now'to Figures 3, 4, andf5riinwhi'ch three p'o'sitions cf-the-=1 im it 'swit'czlr are-shown schematically: Figure 3' illustrates "the tlirnit switchin the contact-open positionfherein called the-hot trip position occasioned by the condition responsive element 22 responding. to a temperature in excess of 200 F., the set limit temperature; Figure .4 illustrates the limit switch in the contact-closed position; herein called the cold trip" position occasioned by the condition responsive element 22 responding to a temperature below 180 F., th differentially determined temperature; and Figure 5' illustrates the limit switch in the contact-open position, herein called the fail safe position occasionedby failure of the condition responsive element 22 or its cooperative parts.

Operation of the limit switch from the cold trip position of Figure 4 to the hot trip position of Figure 3 will now be described. As a rule the temperature responsive bulb (not shown) is placed in the furnace bonnet to respond to bonnet temperature. The bulb communicates temperatures changes in the bonnet to the expansible bellows through a connectingtube (not shown). When a fluid filled system is used, temperature increases cause expansion of the fluid which can be expressed in movement of the diaphragm 26 upwardly. Assuming that the heating system is calling for heat (in response to room thermostat demand), the continued rise in temperature in the furnace bonnet is reflected in an upward movement of diaphragm 26 of condition respon sive element 22. With a temperature increase to 200 F. the following action occurs: gimbal cars 38 and 39 move upwardly pivoting the entire leverage system (main lever 40, pivot pin 60, and trip lever 62) clockwise about the pivot pin 52 against the bias of spring 14. This unitary movement continues until the abutment finger 12 engages the abutment I06a at which point main lever 40 continues its upward trend but trip lever 62 pivots clockwise about the pivot pin 60. The trip lever 62 is now carrying th right end downwardly into proximity with the magnet 58. The resulting snap action carries thebracket 80 and trip bar 82 downwardly against the extension I46 with a quick opening of contacts (I52-I54). Opening of contacts I52-I54) disrupts the control circuit for the heating system, causing shutdown, etc. This action is similar to the on-fan operation of Figure 1.

Operation from the hot trip position to the cold trip" position will now be described. If the temperature of the bonnet air decreases below 200 F. and continues to fall to a point below 180 F., the following action will occur. The contraction of the fluid in the bellows causes the diaphragm 26 to descend. The spring 14, though a weaker spring than spring I62, has a greater mechanical advantage (due to its location at a longer distance from pivot pin 52) and thereby exerts a force downwardly on the lever assembly (-60-62) in excess of the combined upward force of the spring I62 and the condition responsive element 22 in its present condition. As the pivot pin 60 and lever assembly (40-60-62) descend, counter-clockwise about the pivot pin 52, the system approaches the cold trip position with a change in the effective forces acting on the lever assembly. The abutment finger I2 engages the abutment I60 which exerts a force upwardly on trip lever 62, counter-clockwise about pivot pin 60. The upward force of the condition responsive element 22 is steadily decreasing. The upward force of the spring I62 is increasing due to its greater compression. The downward force of spring I4 is decreasing due tditsgIeatereX- pansion. Thus, the increased upward force of spring I 62 aids the trip lever 62 to change its position from. the .hot trip position of Figure 3 to the "cold trip" position of Figured. With the resulting snap action of armature leg 68 into magnetic attraction with magnet 58 and the release of extension I46 by trip bar 82, the limit-switch contacts (I52-I54) are closed. At this point the lever assembly (40-60-62) reaches a quiescent position wherein the downward force of a spring 14 equals the residual upward force of condition responsive element 22 plus the somewhat negligible upward force of spring I62 which has been released by the snap action from compression. The condition responsive element 22 has a residual force upwardly in the cold trip position, because at the time of filling the fluid fill system an initial deflection wasprovided for by forcing the fluid into the system and under ordinary room temperatures a slight expansion or deflection is evident.

The fail safe operation will now be described (Figure 5). With the system as shown in Figure 4 the forces above mentioned are equal. The fall safe. feature of this invention provides for shut down of the heating system upon failure of the condition responsive element 22. As heretofore mentioned; the lever assembly (40-60-62) maintains a position of equilibrium in Figure 4 because of the equalization of forces, one of which is the residual upward force of the condition responsive element 22. It is to be noted that at the "cold trip position of Figure 4, the spring I62 has expanded to its normal position because of the snap action which spread the levers 40 and 62 apart. In case the condition responsive element 22 has failed for any reason, the removal of the residual upward force at 38 causes the spring I4 to continue the downward motion of pivot pin 60 and levers 62 and 40. The additional downward or counter-clockwise movement of main lever 40 about pivot pin 52 brings the head I58 into engagement with the leg I48. This pivots the le I4 counter-clockwise about the branch I50 to carry "contact I52 out of engagement with contact I54. This opens the heating control circuit to prevent operation during the period of failure of the condition responsive element 22. During the .fail safe movement of pivot pin 60 downwardly, it is apparent that the finger 12 again forces the abutment I60'and spring I62 downwardly. This compression of spring I62 creates a force acting upwardly in opposition to spring I4, but this force remains less than the force of spring 12 up to the time of fail safe operation of the contacts (I52-I54). Obviously after that period a point will be reached when the upward force of spring I62 equals the downward force of spring I4, at which point the lever assembly comes to rest. Therefore, it is important to adjust the head I58 so that it actuates the contact leg I48 prior to that point of quiescence; otherwise the fail safe arrangement will not function to shut down the heating control system.

Referring now to Figure 6 in which a modified fail safe arrangement is shown, the corresponding parts are indicated by identical numbers and similar parts are indicated by identical numbers with the suffix a added.

. In this modification the trip lever 62a is provided with. an extension I10 which is apertured at its end to receive a headed bolt H2. The bolt I;'I2 isadiustably threadedin thebase ofrthe 'egevases casing I ll andis'provided with a head-portion H4 and the threaded abutment portion I16.

' The magnet 58a is secured to the base of the casing iiiinsteadof to themainlever 40 as in the embodiment of Figure 5.

condition responsive element 22 has resulted, the

spring M moves the main lever 48a and pin 68 downwardly or counter clockwise about the pivot 52. k

'The finger 12a (in-the doldtrip position) is already abutting the abutment Hit. ther downward movement of pin .60 and'finger 1211 causes trip lever 62a and its component finger 12a to pivotcounter-clockwise about the abutment I80. This movement continues until the extension Ht engages the abutment portion HS of bolt H2, at which time the trip lever 62a reverses its direction and moves clockwise about the abutment lit. The pivot pin Bi! in both instances operates as a hinge instead of a pivot point. This movement results in a snap action of armature leg 1|] into engagement with magnet 58a and the opening of contacts 052-454) by trip bar 82.

It is apparent that'this. modification utilizes the same trip bar 82 to open the switch as in the hot trip function. Obviously, the device could be utilized to control a valve or other control function and'the utilizationof' aswitch was merely for purposes of illustration.

Many modifications and substitutions are possible in this invention 1 and it is. intended to be limited only by the scope of the appended claims.

' What is claimed is:

1. An actuatingvmechanism for operating a control. instrumentality.comprising, a. condition responsive element, a main. lever pivotally mounted intermediateits ends and movableby said condition responsive element,- a trip lever pivotally connected at one'of' itsends to'said main lever, a spring acting in opposition tomovement ofsaid condition responsive element in one direction, a pair of abutments forengagement with said trip lever, and a control instruinentality op erated by said triplever after apre-determined distance of travel of said trip lever'results in engagement of said triplever with one of said pair of abutments toefiect such operation.

v 2. Anaechanism for actuating a control instrumentality comprising, a conditionresponsive element, a first lever movable by said condition responsive element about a fixed pivot,.a spring opposing movementof said first lever in one direction of travel and aiding movement of said first lever. in another direction of travel,- a-second lever pivotally mounted at one of its ends on said first lever and mova'bleabysaid first lever; a first abutment for engagement with said second lever in one direction of travel of said'seoend lever, asecnd abutment for engagementwith saidsecond lever in another direction of travel of said second lever, said abutments engaging said second lever at a point intermediate its free end and its pivotally mounted end, a switch mechanism operable to a first position by said second lever after engagement of said second lever with said first abutment and operable to a second position by said second lever after engagement of said second lever with said second abutment, and a member connecting said first lever and said switch mechanism whereby continued movement of said first lever in said one direction moves said member to The furoperate said switch mechanism-to said second position.

- 3. A mechanism-for actuating a control instrumentality comprising, a casing, a conditionresponsive element fastened to said casing, a main lever movable-by said condition responsive element about a fixed pivot, a spring opposing :movement of said main lever in one direction of travel and. aiding movement of said main leverin another direction of travel, a movable pivotcarried by the free end of said main lever, a trip lever secured to said. movable pivot and movable by 'saidmain lever, an abutment finger on said .trip lever, a first adjustable abutment forengagement with said abutment finger in one direction of travel of said trip-lever, a second adjustable abutment for engagement with said abutmentfinger in another direction of travel of said trip .lever, a first indicating, means for said first abutment, a second indicating means. for said second abut-- ment, a scale for said first and second indicating means, a trip bar connected to the free end of said trip lever, a switch mechanism operated to a first position bysaid trip bar after engagement of said abutment finger with said first abutmentand operated to a second position by said. tripbar after engagement of said abutment fingeiiwith said second abutment, and manual .resetmeans connected to said switch mechanism to. operate said switch mechanism to saidfirst position.

4, In a fan control mechanismthe combination of, a casing, a condition responsive element rastened to said casing. and providing .linear motion, a fixed pivot, a first lever operated by said condition responsive element to mov'eabout said pivot, a movable pivot carriedbysaid firstrlever, a spring biasing said movable pivot and saidifirst lever in one direction of travel,..a secondrlever connected to said movable Divot, an abutment finger on said secondlever,- afirst abutment for engagement with said abutment fingerin one direction of travel of said secondlever, a second abutment for engagement withv said abutment finger in. another direction of travel. .of said second. lever, said abutmentsengaging said abutment finger at ,a point intermediate the free end and the pivotally .mounted end of said-second lever, a-trip bar connected tothe free. end of said second lever, a switcharm. engaged by said trip bar in one direction of travel of. said second lever to actuate a switchand manual. reset. means operated independently. of said lever means to actuate said switch.

'51 In. a switch actuatingmechanism the-combination of, a. condition responsive .element,,a main lever operableby said condition responsive element about .a .fiXedpiVOt, a -movable. pivot mounted. on the free end of saidmainlever, a springv opposing movement of said movable-pivot and said. main lever, a trip lever connected at one ofits-ends to said movable pivot, an abutment finger on said trip lever, afirst abutmentfonem gagementwith said abutment finger in one direction of travelof said trip'lever, a second abutment for" engagement with said abutment finger in another direction of travel of said trip lever, said first and second abutments engaging said abutment finger at a point intermediate the free end and the pivotally connected end of said trip lever, an extension on said trip lever extending in a parallel but opposite relation to said abutment finger, a third abutment for engagement with said extension at predetermined distanc of travel of said trip lever after engagement of said abutment finger with said second abutment, and

1 l a switch mechanism operated to a first position by movement of said trip lever in one direction and operated to a second position by movement .of said trip lever in another direction and operated to said first position upon continued movement of said trip lever in said another direction beyond a predetermined limit.

6. A .mecham'sm for actuating a contral instrumentality comprising, a condition responsive element providing linear movement, a main lever movable by said condition responsive element about a fixed pivot, a spring opposing movement ,of said main lever in one direction of travel and aiding movement of said main lever in another direction of travel, a movable pivot carried by thefree, endof said main lever and movable connected end of said trip lever, a trip bar connected to the free end of said trip lever, and a control instrumentality operated to a first position by said trip bar after engagement of said abutment finger with said first abutment and operated to a second position by said trip bar afterengagement of said abutment finger with said second abutment.

, 7. Amechanism for actuating a limit control switch comprising, a condition responsive element, amain lever movable by said condition responsive element about a fixed pivot, a movable pivot carried by the free end of said main lever, a spring opposing movement of said movable pivot in one direction of travel of said main lever and aiding movement of said movable pivot in another direction of travel of said main lever, a trip-lever connected to said movable pivot and movable therewith, an abutment finger on said trip; lever, a first abutment for engagement with said abutment finger in one direction of travel or said trip lever, adjustable means for raising and lowering said first abutment, a second abutment for engagement with said abutment finger another direction of travel of said trip lever, an abutment spring biasing said second abutment in one direction, a trip bar connected to the free end of said trip lever, a switch operable to a first position by said trip bar after engagement of said abutment, finger with said first abutment and operable to a second position by said trip bar after engagement of said abutment finger with said second abutment, and a, member connecting said switch with said main lever whereby said switch is operated to said first position by continued movement of said main lever below a predetermined minimum operating point of said condition responsive device,

8. An actuating mechanism for a switch comprising, a casing, a condition responsive element providing linear movement fastened to saidcasing, a pivot pin secured to said casing, a main lever movable about said pivot pin in response to movement of said condition responsive element, a movable pivot carried by the free end of said main lever, a trip lever secured at one of its ends to said movable pivot, a spring biasing said movable pivot in one direction, a trip bar secured to the free end of said trip lever, a first abutment engageable by said trip lever in one direction of travel of said trip lever, a second abutment engageable by said trip lever in another direction of travel of-said trip lever, said abutments engaging said trip lever at a point intermediate its free end and its pivotally secured end, and a switch operated to a first position by said trip bar after engagement of said trip lever with said first abutment and operated to a second position by said trip bar after engagement of said trip lever with said second abutment.

9. A control mechanism of the type utilizin a liquid expansion temperature responsive element comprising: pivotally mounted switch blades, cooperating contacts carried by the switch blades and biased to closed position, motion transmitting means comprising a pivotally movable lever system interposed between said element and said switch blades, means forming a part of said lever system for engaging and pivotally moving one of said switch blades to open said contacts as said leversystem is moved in one direction by said element, said means releasing said one switch blade to close said contacts as said lever system is moved in the other direc tion, a trip member extending from said lever system and engaging another of, said switch blades after movement of said lever system sufiiciently in said other direction to thereby open said contacts independently of said means.

10. A control mechanism of the type utilizing aliquid expansion temperature responsive element comprising: acasing supporting said element and a pivot pin, a main lever pivotally mounted intermediate its ends on said pivot pin, a secondary lever pivotally mounted at one of its ends on said main lever and extending in overlying relation therewith, a spring biasing said main and secondary levers in one direction, an abutment finger on said secondary lever, a, trip bar connected to the free end of said secondary lever, opposing'flxed abutments adapted to be engaged by the abutment finger as th main lever is moved by said'element, and switch control means cooperable with said trip bar of said secondary lever.

JURG A. SENN.

References Citedin the file of this patent UNITED STATES PATENTS Number Name Date Re. 17,304 Knaak May 28, 1929. 733,561 Sundh July 14, 1903 2,389,436 Kearney Nov. 20, 1945, 

